ABSTRACT
Objective To prepare polymersomes (PSs) by block copolymers,evaluate their membrane structural stability,investigate the H+ transmembrane permeability of PSs and the impact of 1,4-dioxane and establish a foundation for drug encapsulation within polymersomes. Methods PSs were self-assembled by a block copolymer, PEG-PLGA, in a solvent solution. The pH-sensitive fluorescence probe HPTS was employed to examine the H+ transmembrane properties of PSs and compare them with PSs prepared using PBD-b-PEO, PS-b-PEO, and liposomes. The effect of varying concentrations of 1,4-dioxane on PSs’ membrane permeability properties was also investigated. Results The fluorescence excitation spectra of HPTS exhibited pH dependency, which showed a linear correlation between extravesicular H+ concentration and t1/2. Significant differences were observed in the membrane permeability capabilities of PSs with different membrane wall thicknesses. Compared to liposomes, the H+ transmembrane coefficients for the three types of PSs were reduced by 2.39×104, 3.38×104, and 5.48×108 times, respectively. 1,4-dioxane was found to modulate the permeability of PSs’ membranes, which displayed a concentration-dependent relationship. Conclusion PSs exhibited significantly lower membrane permeability compared to liposomes, indicating superior stability. 1,4-dioxane was identified as a modulator of PSs’ permeability, which offered potential for drug loading and release within PSs.
ABSTRACT
As a type of extracellular vesicles, exosomes are released by living cells and contain diverse bioactive molecules, including nucleic acids, proteins, lipids and metabolites. They play an important role in various physiological and pathological processes by a special intercellular communication medium. As endogenous vesicles, exosomes also have the advantages of systemic circulation stability, good biocompatibility and specific targeting of tissues and cells, as well as they are promising candidates for drug delivery system. The production mechanism of exosomes describe was summarized, the methods of extraction and separation the application and mechanism of exosomes in immune and inflammation-related diseases, cardiovascular system diseases, nervous system diseases, tumors, etc. were reviewed. The engineering modifications of exosomes in high targeting properties based on the drug delivery were overviewed. Exosomes support the diagnosis and prognostic assessment of multiple diseases, which have broad application prospects as a very potential safe and specific endogenous nano-drug carrier.
ABSTRACT
Nanocarriers prepared from organic or inorganic materials are widely used in drug targeting system and diagnosis and treatment of disease. However, there are some problems, such as poor targeting, short circulation time in vivo and improvement in the biocompatibility. Biomimetic nanocarriers has carried out research on the issues, which based on different kinds of cell membrane for the nanocarriers modification, endogenous biofilm improving the biocompatibility of carriers in vivo, more accurate targeting, and even producing immunotherapeutic effect. The principle, method, targeting mechanism and therapeutic effect of biomimetic nano carrier technology of cell membrane have been reviewed in this paper, which provide a new direction for the research of new drug delivery system.
ABSTRACT
Objective To prepare a biomimetic nano carrier macrophage membrane hybrid liposome by heterozygous macrophage membrane and liposome, which could be used for the clearance and toxicity inhibition of Vibrio vulnificus hemolysin A (VvhA). Methods Macrophage membrane was extracted and hybridized with liposome by thin-film evaporation combined extrusion method. The hybridized liposome of macrophage membrane was constructed and characterized. The in vitro detoxification ability of the hybridized vector was evaluated by hemolysis test and cytotoxicity test. The detoxification ability of the vector was evaluated by mouse skin infection model. Results Anti toxoid studies in vivo and in vitro showed that the anti-hemolysis rate of macrophage membrane heterozygous liposomes in vitro reached 97.03%, which could effectively inhibit the skin ulceration in subcutaneous infected mice and make the survival rate of abdominal infected mice reach 80%. Conclusion The constructed macrophage membrane hybrid liposome had high detoxification ability, which could provide a potential solution and research basis for the prevention and treatment of Vibrio vulnificus infection.
ABSTRACT
Objective To prepare and optimize the formulation of Albumin nanoparticles loading PROTAC molecule and observe the inhibition effect of nanoparticles on the proliferation and NAD+ metabolism of glioma cells. Methods Albumin nanoparticles loading NPT-B2 were prepared and characterized with a thermal driving method, and the prescription was optimized. An HPLC method was established to determine the content of NPT-B2. The proliferation inhibition of NPT-B2 and B2-BSA-NPs on U251 cells were investigated by the CCK8 method, and the degradation effects of NPT-B2 and B2-BSA-NPs on NAMPT in glioma cells were investigated by western blotting. Results The HPLC method was stable, with good linearity, precision, and recovery rate. The nanoparticles had a particle size of about 55.48 nm, a potential of about −12.9 mV, an encapsulation rate of about 94.74%, and a drug loading amount of about 8.61%. The IC50 of NPT-B2 on glioma cells was 61.16 nmol/L, which had a degradation effect on NAMPT. The IC50 of B2-BSA-NPs on glioma was 41.21 nmol/L, which had a very significant degradation effect on NAMPT. Conclusion Albumin nanoparticles loading PROTAC molecules were constructed. The prescription was optimized to improve the drug encapsulation rate, and the low water solubility of PROTAC molecule was improved, which had a significant inhibitory effect on the proliferation and NAD+ energy metabolism of glioma cells.